Sistema F.E.E.

ABSTRACT

The invention is a different scheme plant which changes radically the method of conception of all refrigeration systems, conditioning and heat pump. Sistema F.e.e. shocks all previous concepts regarding the disposal of process heat coming from any industrial production. Sistema F.e.e. is an integrated system in an artificial environment which recovers and utilizes each possible source of thermal energy, to the limit of utilizing the thermal energy which comes from scraps of production auxiliary to its own disposal. 
     Sistema F.e.e. has been the beginning of the third great industrial revolution, which is the energetic revolution in respecting nature. Sistema F.e.e. is instead integrated to nature; our system is the point of beginning which marks the end of the oil and petroleum era.

BACKGROUND OF THE INVENTION

Sistema F.e.e. starts as auxiliary to the production of hydrogen through the electrolysis of water but finds its best application in the functioning of refrigeration systems and heat pump, which will turn out to be better and they (refrigerator and heat pump) will work in any climate atmosphere.

Sistema F.e.e. makes possible the elimination of chemical combustions solving in away fully ecological (and with economic advantages) the problem of the co2 emissions and of the pollution of the urban centers. As previously indicated: Foreign Italian Patent (ITALY 0001364443) granted Jul. 29, 2009 and filed originally on Dec. 23, 2005.

BRIEF SUMMARY OF THE INVENTION

Sistema F.e.e. is the integrated system which picking up thermal energy from different sources, it is able to move this energy inside the destined environment and in doing so surpasses and provides a solution to all previous mistakes of refrigeration and conditioning systems and heat pump. All the renewable and natural energy sources are put together for the functioning of our system which picks and redistribute energy from the air, sun and water. Sistema F.e.e. betters productivity of solar panels; moreover it can re utilize the energy which is scraps of production as kinetic energy; this will enable for a better performance of the system as a whole.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING

FIG. 1 shows the main functional scheme of the system assembled as a whole. FIG. (from now on FIG.) 1A, 1B, 1C, 1D, 1E, are the 5 components which together build FIG. 1. The view of the renamed FIGS. 1A, 1B 1C, 1D, 1E, is the same view as from FIG. 1 (main functional scheme), they are zoomed in showing the different parts and description of each single component; for a better understanding refer to the detailed description of the invention.

Note that FIG. 1B is the core of the system. FIG. 1B assembled with FIG. 1A, 1C, 1D, 1E, to show FIG. 1. However it is here in FIG. 1B that the activity from the physical principle utilized develops to obtain its final result.

FIG. 1F and FIG. 1G are specified and described in the detailed description however they only represent heat or cold fluxes and indicate the origin of the energetic fluxes which will be used, and are useful to better understand the meaning of this invention and its value.

These two figures are not included because unnecessary.

DETAILED DESCRIPTION OF THE INVENTION (DESCRIPTION OF THE PREFERRED EMBODIMENT)

Sistema F.E.^(E). Fattore Energetico Esponenziale.

The system named Sistema F.E.^(E). (Fattore Energetico Esponenziale that means Exponential Energy Factor) is the system, in an electrically controlled environment, for the control of a determined quantity of energy (at a given time) in the transformation of the vector, water, to the ratio of the entry of heat and its transformation in pressure/kinetic energy. From this point the system will be called Sistema F.E.^(E). Sistema F.E.^(E). system is intended to support any type of refrigeration (cooling) and its best use is found to be as a support for the condensation of the “technical gas” produced by refrigerators using mostly or partially just water. As a matter of fact, Sistema F.E.^(E). has been specifically studied and built to rationalize consumption of water and recover energy (in form of heat, pressure or kinetic energy) produced by the systems themselves.

Sistema F.E.^(E). is always useful and extremely efficient in the temperature control of electrical solar panels Bi-functional. Moreover being them used in an intrinsic way to produce heat, they will turn out very useful and extremely convenient. The system can be used with any system which produces heat. Industrial refrigerators systems are the ones most favorite by using our system, the successfully ones make circulate technical gases circulate inside a hermetic circuit which uses a compressor, condenser, expansion valve, or capillary evaporator (static or ventilated).

The figure in the main functional scheme (FIG. 1) shows the representation of the phenomenon created from the point of view of the mechanical management service. The heat, in so called cool chain, produced by work in any system to the present day has always been considered as annoying scraps of production and therefore eliminated. Now, keeping in mind that refrigerator systems work thanks to thermal exchange, with a certain advantage toward the heat, we must consider that with the systems currently in use the energy used accounts in percentage as 50% inferior with respect to the initial goal. During traditional cooling and conditioning (summer phase) the heat is eliminated, during the conditioning by heat pump (winter heating phase) the cold is eliminated.

Sistema F.E.^(E). is useful and innovative because it completely uses the energy employed, for example: during the winter cycle it will recover the heat from the traditional cooling system and at the same time the cold from the heat pump.

Sistema F.E.^(E). is made of (see FIG. 1B):

-   1. Water evaporator and condenser Shell tube -   2. Flow switch -   3. Sistema F.E.^(E). circulator (pump of circulation in an equal     system) -   4. Manual valve -   5. Discharge for maintenance -   6. Check valve -   7. Excess pressure valve -   8. Thermostat probe critical point -   9. Two ways control valve -   10. Water exchange for solar evaporator -   11. Drainage control system -   12. Manual valve for bypass emergency -   13. Anode sacrificing.

This is the core of Sistema F.E.^(E). system which is assembled with all that is described below, however it is here (FIG. 1B) that the activity from the physical principle utilized develops to obtain its final result. The introduction of the heat from the utilization and from the rest of the system tends to raise the heat from which, in a closed environment, water will tend to increase in volume and, when contained it will increase in pressure. On the side of the heat pump, during the winter cycle, the subtraction of heat, approaching freezing temperatures, causes the same phenomenon of increasing volume. Water getting close to the freezing point tends to expand and float, making it lighter; in our system it is contained and by doing so, it will push going down through the only traversable way. Once more the pressure transforms into kinetic energy, becoming useful for our goal. The rising of the cooling will rise proportionally the pressure and consequentially its transformation in kinetic energy, which will become useful work useful to the same subtraction itself of cold. The containment of water brings consumption of energy (heat or cold) to obtain a raise in pressure.

When taking in consideration a traditional fridge, the heat or the cold are just scraps of production; consuming them to transform them into new levels of energetic expression will ease the disposal. Easing, the disposal of it is part of the job done by Sistema F.E.^(E). system, make not only that, but water consumption will also be less. So our system can be used as disposal of heat reducing the consumption of water destined for the initial purpose. Even cooling a thermonuclear facility would be possible, and a nuclear central by fusion also, when technology will be available, the cooling of a nuclear facility as well.

Sistema F.E.^(E). system can substitute, worthily and with economic advantage, not to mention functionally (the functioning), cooling towers and/or other means of remote disposal of heat and cold.

The (water) storage tank must be proportioned to the needs of the machinery, one of the goals is to be able to use the energy at different times (which is accumulated in form of heat/pressure/kinetic energy) and to take the best advantage of all characteristics of the element water; in its physical, mechanical and dynamic states in its specific behavior. The pump is found in a flying position, taking advantage from the push thanks to the weight and pressure of the above water, it receives it with lower temperatures (or higher temperatures in the case of the subtractions of heat in a heat pump) compared to the storage media.

The position picked for the recycle pump is calculated on the base of different quotients resisting the flow; once at the start point, it is gone and given the right direction to the flow: that same pressure will find its outlet through the pump, facilitating the movement. When the system is closed the pressure is increasing, caused by the continuous rise in heat (or cold), it will tend to outburst out of the only possible exit; consequentially to the work of the circulator and above weight, vice versa for the return in position with minimal resistance, in this way all the system will be advantaged. The speed of the flow will go through variations in natural response with respect to the needs of the system.

The maximum consumption registered on the whole system (including recycle pump), in a closed system with pressure coming from the pipes underground is at most as big as 2,6 electric kwh in plants capable of disposing 600 caloric kwh.

The two way valve with modulated mechanized movement has more than one function: it regulates the temperature of the water for the right functionality of the refrigerator systems, it expels air, it evacuates vapors, it keeps water clean and the system's total pressure. The above valve takes command from the probe placed in the (critical point) hottest (or coldest) spot of the entire system. The operator through the electronic control system, decides that the above temperature must not surpass the predefined threshold (also, at the same time, go below a pre determined temperature).

Thanks to this method it is guaranteed that inside our system we will only have lower temperatures (or superior ones in the case of reversal cycle. The critical point, maximum or minimum temperature, for the physical phenomena already described will be the same).

If needed, eventually, the integrated system of recuperation for the recovery of energy will establish a threshold for the maximum temperature, the minimum and, for every single system connected to it, the threshold of intervention of security of active anti coolant. This will happen by the reversal of the refrigerator system (circuit), in the critical points or the ones pre chosen to the goal. Before the two way valve modulating and in priority position we have a connected valve for all the needs requested: hot water, disposal in the restrooms, sprinklers system and anything that can turn out to be useful.

Sistema F.E.^(E). system is connected to the municipal (hydraulic net) water or well of first water founded and the pressures inside of it will start from the very same ones connected to the municipal, or any else hydraulic net, pipes. Sistema F.E.^(E). system also has an outlet, in the lower part of the tank, for the total emptying of the system (maintenance use). For example: anti limestone treatment or generic cleaning of the tank from the production of sludge or other residuals which can form due to scarce use of the system.

In the upper part of the tank there is also another exit connected directly for the safety valve (pressure). Sistema F.E.^(E). s cycle expects the raising of the pressure in a directly proportional way to the flow of heat or cold. The excess pressure valve other than being a safety precaution is functional to the system and in determined circumstances it has need to free pressure instead of heat or cold. Finally, on the same line, it is found the exit given by the safety bypass destined to maintain the efficiency in case we had to temporarily exclude our system for ordinary maintenance or other extra needs.

With the use of Sistema F.E.^(E). system all the water used for the condensation becomes available for civil use and will be using the energy which otherwise would have been wasted. The water used for the cooling of refrigerator systems with Sistema F.E.^(E). is being used now for domestic purposes and is not considered as wasted anymore. The functional usage is not necessary; however, it betters the economic advantage of the system.

Putting the temperature of reference for the civil use of hot water at 98.6 F (shower temperature) any boiler will receive municipal water from 39 F and 57 F and it surpasses a thermal differential which varies from 73 F to 91 F. With Sistema F.E.^(E). the thermal differential will be from 32 F to 46.4 F depending on the season and the flux of heat, with the example of refrigerator systems, with savings on consumptions which will be always noticeable.

The system of accumulation when built at its best, meaning in a way proportioned to the quantities needed, will let the temperature of the water rise or fall until the limit that we have fixed; the quantity discarded from the motorized valve on top of the tank is minimal. This same valve has only the function to regulate, and will never discard more than 10% of the normal consumption of water; the reduction of the consumption of water destined to the condensation of the fridges will be 90%.

Sistema F.E.^(E). system is made for a full recovery, when this is useful of the process heat coming from any heat source which in this case becomes ‘useful job’. This is very useful towards the bi-functional photo voltaic solar panels (simply electric solar panels). This due to the fact that under controlled temperature they will raise the electric power generated. But at the same time Sistema F.E.^(E). is able to put and use integrally both energies (thermal and electrical) and, thanks to this great advantage, it betters ways of management.

Particularly it's ideal to manage the heat of gap (or discard) from any regular refrigerator system can heat up our system which has became the outside environment, but artificial and controlled at the same time; going to rise the temperature of the environment where the evaporation of a regular heat pump which now is put in environment temperatures for the evaporation between 69.8 F and 77 F will bring a COP much superior (bringing to instantaneous COP of 16 and COP of 8 minimum seasonal mean).

In the functional scheme (refer to FIG. 1C) it is represented a normal refrigerator system with the adapt scheme to operate synergistically to the Sistema F.E.^(E). system:

-   1 Shell tube -   2 Compressor -   3 Crank-case heater -   4 Manual valve -   5 4 way valve cycle inversion -   6 Check valve -   7 Excess pressure valve -   8 Tell tale of the liquid -   9 Tank of liquid separator -   10 High heat exchanger (it is used to give hot sanitary water at 131     F) -   11 Cartridge filter -   12 Transducer and manometer -   13 Differential oil manometer -   14 Exchanger side users for heating or cooling -   15 Pressure switch and transducer high pressure -   16 Vibration damping -   17 Thermostatic valve -   18 Electronic valve -   19 Inverter control pressure -   20 Air condenser.

With the intent to freely use the process heat to the “integrated” and “total” method we will use the scheme described in FIG. 1A. To better show this, let s consider a refrigerator system in which we describe the condensation, however the same scheme can be applied to any other form of heat.

-   1. Air capacitor, energy source. -   2. Check valve -   3. Solenoid valve (electro valve) -   4. Manual valve through by pass -   5. Condenser or exchanger to transfer energy to the system.

The solenoid valves regulated through electronic device will deviate all the heat available from the system, going to condense in our water condenser shell tube and not anymore in the outside environment. In the air condenser to the point reputed valid from the operator (necessary and convenient) following the scheme from FIG. 1A.

With Sistema F.E.^(E). system finally it is possible to consider what was earlier a waste like an energy source; it is logical from this finding that it is possible to use any font of energy, also the one coming from solar (hydro-thermal) panels or electrical solar panels from their own water cooling circuit.

While the heat process is an energetic font which only needed extra work to dispose of, now this is an energy font free and infinite, to add and use just like the scheme shown in FIG. 1E. If they can solar hydro-thermal panels, in our functional scheme, are used for the achievement of the right temperature as free energetic font for the production of hot water destined for sanitary use; but when they don't reach suitable temperature, the heat that will still be produced by them will come into play into the idea of integrated system.

Following the scheme described in FIG. 1E it is noticeable how the heat produced is put again into play; for example during the summer from a normal air conditioning system for the production of hot sanitary water and how, instead, the heat coming from the solar source can go and raise the temperature of the evaporative phase of our heat pump raising the COP over 8 points.

-   1 Vase of expansion circuit user hot sanitary water -   2 Line sent hot sanitary water using -   3 Entrance for municipal water -   4 Manual valve -   5 Resistor for well being and emergency hsw -   6 Check valve -   7 Overpressure and safety valve -   8 Thermometer -   9 Safety Thermostatic -   10 High exchanger -   11 Manometer -   12 Maintainance valve -   13 Water circulator -   14 Solar panels -   15 Pressure reducer -   16 Jolly valve (deaning valve) -   17 Solenoid electro valve -   18 Electrical solar panels bi-functional -   19 Power supply for instance 12 volt or 24 volt -   20 Power supply for instance 220 volt -   21 Power supply for instance 380 volt -   22 Water cooling circuit of electrical solar panel -   23 Emergency control valve for over heat in solar cell valve, it is     useful to correct the electrical production linked at panels works'     temperature.

The best relationship on both the components usually is obtained with temperatures between 69.8 F and 77 F which makes it more convenient, even just for transitory phases, to come back to the condensation in external air environment.

Water cooling circuit of the electrical solar panel (bi-functional) will profit every electrical advantage keeping it in controlled temperature and with its own heat it will be helping the system when required.

When using this kind of electrical solar panels, right calculated, the entire system and its own electrical consumption will find satisfaction from the solar panels only. From now on everyone will be able to choose if and when to use a normally electricity grid, or integrate it with solar electrical production or, under certain circumstances, to build an all free energetic systems (stand alone).

When during particularly positive conditions (outside weather) outside air can be used for the cooling of the circuits Sistema F.E.^(E). system is given a cooling/condenser proportioned to the needs and compatible with the overall functionality. Once again, if Sistema F.E.^(E). system is fully built at state of the art and with materials which are compatible to the domestic use of water, there will be no direct contacts from different fluids and the thermal exchange and its vehicular to the use happens through the materials certified also by sanitary use.

The materials more adapt for the various uses are: copper, stainless steel, bronze, titanium, ceramics, zinc-coated iron, enameled iron, polypropylene copolymer random. The thermal exchange with the refrigerator systems will be in the coaxial pipes made in copper or in the shell tube, made out of copper and/or steel and/or titanium, designed ad hoc to be able to respond to the sanitary needs and specific characteristics for the quality of the water as the rest of the system. Titanium, for example, is used to the thermal exchange vapor/water sea water/potable water.

Sistema F.E.^(E). is useful and innovating also because making convenient the use of water for the cooling of the condenser, it eliminates or reduces the usage of fans, used in the cooling process by air. Their consumption is eliminated with a direct saving of an additional 10%-20% of electric energy on the total consumption, bringing even grater productivity.

Sistema F.E.^(E). system has completely solved the problem of noise; without any fans it is possible to create soundproof from the condensers, which finally will be able to be shut and closed without any need of contact with the outside air and so diffusion of noise will be reduced at less or nothing.

Sistema F.E.^(E). system was made possible thanks to the technological advances which made possible an electronic system capable to ease the control and the stability of the system itself, other than from the precise and punctual compression of the physical phenomenon, visible in nature, which results in the phenomenon called Tsunami, and its possible applications in a controlled environment.

A tsunami can be caused by three phenomena:

-   1. As a consequence of an underwater earthquake, the movement of the     earth's crust generates the wave which will expand in a chaotic and     anomalous way compared to the natural swell. -   2. A collision of two layers or the breaking of the earth's crust     will release a chain effect which will ultimately result in the     above wave. -   3. The third is a phenomenon which is referred to here: an eruption     deep underwater. Here, the action of the compression which occurs is     caused by both the weight of the above liquid (that holds for a     short period of time before the energy, produced by heat, gets     released. Water cannot go from liquid to vapor; here, the pressure     rises as a natural answer to the compression of the above liquid     until a state of ephemeral equilibrium (or a stall state); this is     the instant in which we would be able to calculate exactly the     quantity of energy present at that particular moment. This will be     the result of the water pushing on the magma and vice versa: the     quantity of heat expressed by the volcanic eruption in turn     compressed by the above water. The break of this equilibrium looses     kinetic energy the lower down pressure made in the moment of stall.     The break of this equilibrium looses the kinetic energy formed by     the pressure made in the moment of stall. -   4. Very often the phenomena behind “the tsunami effect” happen at     the same time: a break of the earth's crust with emission of     underwater volcanic magma or eruption of magma with the terrestrial     movement or clash between pitches with ensuing earthquake and break     of the crust with eruption. -   5. The phenomenon of the development of heat in pressure in a     controlled (and managed) environment is the main object of this     patent and its new technology.

The heat is at the base of the energy pyramid, in particular the element of water has peculiar behavior towards heat. These answers to the sum and subtractions of heat in the element are common knowledge. The element tends to rise in volume the closer it gets to the changes in state and if it gets mechanically held which will automatically cause the pressure to rise. The water, once again, tends to rise in volume and this is “work” in both cases (add or remove heat). Sistema F.E.^(E). system also uses this energy; the increase of the volume in water due to freezing is a very powerful and unstoppable force.

Our system proposes to utilize this phenomenon as well to improve the performance of the cooling systems using a heat pump. Water will rise in volume and become lighter, it will then naturally flow higher inside the tank. Water kept inside the tank will automatically have the same behavior described above: rising volume in the higher part of the tank will work as a propeller through the only way out, which is the pump in flying position.

This useful work, in a system with heat pump is obtained by the subtraction of thermal energy and will eventually become “useful work” in the production of thermal energy. The speed the water is going through the exchangers will grow, and with that the mass of exchange, facilitating the disposal, proportional to the cold received. This institutes a very powerful and noticeable improvement of the services of any conditioning system with heat pump.

We can utilize this phenomenon during the transition phase when the volume rises from 38 F to 33.8 F phase which anticipates freezing point and during which the expansion of the water is between 15% and 20%. The real power of this phenomenon must be calculated adding the energy which is subtracted by the movement produced because in this particular situation they are both “useful work”. In doing so, suggesting its use is a marvelous scientific advance. This technique utilized in a heat pump raises the performance and extends the functionality beyond anything known up to the present day. The application of Sistema F.E.^(E). system is innovative because it adds to any conditioning system working with heat pump, a thermal and energetic area of functionality further, which is a new concept, that never before could have been possible to use.

It is water, the immense container of ecologic energy, renewable and natural; it covers 70% of the earth's surface and so it is the easiest element available. For the functioning of Sistema F.E.^(E). system the quality is not an indispensable requisite, it can be of good or bad quality, salty or not; these issues are solved by the accurate choice of materials by which the system is built with. By these means Sistema F.E.^(E). system is perfectly suitable with the electric heating systems using heat pumps. The increase in earning where we can recover the heat produced by refrigerator systems is very noticeable.

Where heat or absorption of heat are considered scraps of production its transformation in pressure, in a controlled environment, will help the disposal, but during winter when the heat pump in the conditioning system works in inverse cycle, all the heat (scrap in this case) comes from any source (for example the industrial refrigerators' circuits or cooling of any type of manufacturing) is transferred and utilized completely for the heating.

This process will be happening before the use of the disposal of water and to the exploitation of the thermal energy contained in it. F.E.^(E). is new because other than using this energetic source, it introduces two other fonts of energy (in the heat pump) being the process heat and solar energy using solar panels, which will become productive also at lower temperatures also electrical solar panels: while improving their production capacity of electronic energy at the same time they become one important heat source.

In FIGS. 1F and 1G the energetic fluxes are described in heat and cold following this scheme of energy flux.

FIG. 1F has the energetic fluxes (heat):

-   -   1—Energetic source stratum water (that can be assimilated or         superior in performances and functionality of the geothermic         system). This font guarantees the functionality of the heat pump         at any atmospheric temperature.     -   2—Heat energetic font coming from industrial heat process; for         example the heat produced from the refrigerator systems for the         preservation of food. This heat before considered as scraps of         production is being utilized, also fully, sending it to the heat         pump.     -   3—Process heat to heat pump.     -   4—Solar energy font: this heat energy font is normally used for         the production of hot sanitary water; when the services from the         panels are not sufficient to obtain the temperature of the well         being, these will transform in solar evaporators and will go to         rise the temperature where the heat pump evaporation works. The         heat pump, so assisted, will raise the performance in a way very         noticeable and it will be this to take care of the production of         hot sanitary water, through the high heat exchanger previously         cited.     -   5—Circuit for the solar remote evaporator.     -   6—Circuit of the solar font towards the hot sanitary water.

FIG. 1G shows the use of the cold fonts and their use:

-   -   1—Cold font from the layer: this font guarantees the         functionality of the air conditioner and of the refrigerator         systems at any atmospheric temperature.     -   2—Cold font from the process of environment heating: this cold         font direct through exchange towards the Industrial         refrigeration system; this is another (further) power which is         utilized instead of wasted.     -   3—Subtraction of heat from exchange: when we are using the air         conditioner to produce cold (in environment) this is a free heat         font which betters the performance of the whole system of about         20%.

The winter circuit of a heat pump connected to the Sistema F.E.^(E). system anticipates the use of the renewable fonts in the following order:

-   1. Any font coming from any industrial process is used first     (refrigerators or other). -   2. Solar panels' energy is completely transferred to the heat pump     until satisfactory point. Whenever this energy will not be     sufficient, and during some parts of the year it will be. -   3. We use for second (meaning from fourth to second) the capacity of     dilatation of water as thermal energy. -   4. When there are no more energy sources available, the energy     (thermal energy) will be absorbed from the water which is well known     due to its performances, in any system, which takes on its energy     from the underground is geothermic but better In the functional     scheme (FIG. 1E winter) it is represented a refrigerator system in     both the cycles, working in cold and with heat pump.

Sistema F.E.^(E). system can be used for scientific purposes in any of its possible applications which go from the auxiliary to the condensation or insufficient evaporation, to make the system's use complete and when all the sources of heat (scraps) and all the origins of subtraction of the heat unite, realizing a more complete and efficient recycling (being helped by solar too).

Sistema F.E.^(E). system accumulates heat for a time superior in length compared to the production time and sends it back when needed thanks to the storage that kept the energy overtime. One of the main energetic values of Sistema F.E.^(E). system is the fact that Sistema F.E.^(E). system makes possible and cheap the substitution integrated of the air condensation to water condensation. The merits deriving from the contacts between fluids at the fluid state, for the deploy or subtraction of the heat. The optimal environment created shows how stable and evident this advantage becomes.

Other benefit is directly toward the functionality of the refrigerator systems, being this a dynamic system, subject to the variants of the outside temperatures, have been made to different due to climate change; with Sistema F.E.^(E). the thermal differential is rationalized and by doing so it is finally possible to produce refrigerator systems which are easier, smaller and more stable.

Home builders will have the great benefit to build systems destined to work inside an environment which can mutate from extremely dynamic to static and controlled. During the year the thermal differential which refrigerator systems go through is from 104 F during the summer heat to −4 F during the cold winter. Considering a summer day in the presence of a thunderstorm the range can be even more than 68 F. Sistema F.E.^(E). system can adjust at a maximum of 89.6 F during the hottest period of the year to the minimum of 33.8 F at the coldest period of the year. During the most part of the time in the winter it will arrange between 73.4 F and 77 F, during most of the summer instead at 82.4 F and 89.6 F therefore it is much more precise and manageable. It gives the choice to go from dynamic system, subject to the outside temperature, to a system instead static and controlled fully by the operators. 

1- The acknowledgment of the invention in exploiting the physical principle described above for any system built for condensation, evaporation or cooling. 2- We claim the use of the transformation of energy as a method for the deploy of the scraps of energy and in recognition of how it is Sistema F.e.e. the system for the optimization of the energetic consumption and for the consumption of water destined for the final goal. 3- We claim the use of the Sistema F.e.e. system as a whole or in part for the recycling of the disperse heat, of the solar thermal energy and of the kinetic energy intrinsic to the element and to use it to better the performance of the heat pump. 4- The use of Sistema F.e.e. system for a better refrigeration condensation process and electrical energy production from electrical solar panels, bi functional as well. 